KR20200055119A - Plate packs for heat transfer plates and heat exchangers comprising a plurality of such heat transfer plates - Google Patents

Abstract

A plate pack 2 for heat transfer plates 4a, 4b, 4c and a heat exchanger is provided. The heat transfer plates 4a, 4b, 4c have opposing first and second faces 6, 8 and include first, third and fourth guides 60, 64, 66. In the heat transfer plate, the first and fourth guides 60, 66, when viewed from the first side 6 of the heat transfer plate, are arranged with a first adjacent heat transfer plate for alignment of the heat transfer plate and the first adjacent heat transfer plate. Male protrusions 68, 70 arranged to engage and, as seen from the second side 8 of the heat transfer plate, female legs arranged to engage a second adjacent heat transfer plate for alignment of the heat transfer plate and the second adjacent heat transfer plate Seth 78 and 80, respectively. Further, the third guide portion 64 is a male protrusion 90 arranged to engage a second adjacent heat transfer plate for alignment of the heat transfer plate and the second adjacent heat transfer plate, as viewed from the second side 8 of the heat transfer plate ) And a female recess 100 arranged to engage a first adjacent heat transfer plate for alignment of the heat transfer plate and the first adjacent heat transfer plate as viewed from the first side 6 of the heat transfer plate.

Description

Plate packs for heat transfer plates and heat exchangers comprising a plurality of such heat transfer plates

The present invention relates to a heat transfer plate and its design. In addition, the present invention relates to a plate pack for a heat exchanger comprising a plurality of such heat transfer plates.

Plate heat exchangers, ie PHEs, typically consist of two end plates in which a number of heat transfer plates are arranged in a stack or pack. The heat transfer plates of PHE can be of the same or different types and can be stacked in different ways. In some PHEs, the heat transfer plates are stacked such that the front and rear surfaces of one heat transfer plate are respectively facing the rear and front surfaces of the other heat transfer plate, and every other heat transfer plate is upside down relative to the other heat transfer plate. Typically, this is referred to as heat transfer plates that are “rotated” relative to each other. In another PHE, the heat transfer plates are stacked such that the front and rear of one heat transfer plate are facing the front and rear of the other heat transfer plate, respectively, and every other heat transfer plate is upside down relative to the other heat transfer plate. Typically, this is referred to as a “flipped” heat transfer plate with respect to each other.

In one type of well known PHE called gasketed PHE, gaskets are arranged between heat transfer plates. The end plate and thus the heat transfer plate are pressed against each other by a kind of fastening means, whereby the gasket seals between the heat transfer plates. Parallel flow channels are formed between the heat transfer plates, and one channel is formed between each pair of adjacent heat transfer plates. Two fluids, initially at different temperatures, supplied to / from the PHE through an inlet / outlet can alternately flow through every second channel to transfer heat from one fluid to another, and this fluid can Entry / exit to the channel through the inlet / outlet port holes in the heat transfer plate communicating with the inlet / outlet.

The end plates of gasketed PHE are often referred to as frame plates and pressure plates. The frame plate is often fixed to a support surface such as a floor, while the pressure plate is movable relative to the frame plate. Often, the upper transfer bar for transporting the heat transfer plate, and possibly also the pressure plate, is fastened to the frame plate and extends from its upper portion past the pressure plate to the support column. Similarly, a heat transfer plate and possibly a lower guide bar for guiding the pressure plate is fastened to the frame plate and extends from the bottom portion away from the ground past the pressure plate to the support column.

Since the misaligned heat transfer plates may cause leakage in the PHE, it is important that the heat transfer plates are aligned with each other in the stack in order for the PHE to work properly. The transport and guide bars of the heat exchanger may provide alignment of the heat transfer plate by engagement with the heat transfer plate, but this alignment may be insufficient. In addition, some PHEs may not have transport bars and / or guide bars. In view of this, some heat transfer plates are provided with guides, wherein the guide portions of one heat transfer plate are arranged to engage with the guide portions of the other heat transfer plate for alignment of the heat transfer plates. WO 2010/064975 discloses such heat transfer plates arranged in a stack, where all other heat transfer plates are “rotated” relative to the other heat transfer plates. WO 2010/064975 discloses a guide solution that works very well, but it is limited to the alignment of the heat transfer plates “rotating” with respect to each other.

One object of the present invention is to provide a heat transfer plate that solves the above problems. The basic concept of the present invention is a heat transfer with a more flexible guide than a known solution in that it allows alignment of the heat transfer plate and another heat transfer plate regardless of whether the two heat transfer plates are "rotated" or "reversed" with respect to each other. It is to provide a plate. Another object of the present invention is to provide a plate pack for a heat exchanger comprising first, second and third such heat transfer plates. Heat transfer plates and plate packs for achieving the above object are defined in the appended claims and described below.

The heat transfer plate according to the present invention has opposing first and second faces, outer edges and a central extension plane, and includes an edge portion comprising wrinkles. The crease extends between the first and second planes parallel to the central extension plane, and the central extension plane is arranged between the first and second planes. The pleats are arranged so that when the heat transfer plate is arranged in the plate heat exchanger, it contacts the first adjacent heat transfer plate on the first side of the heat transfer plate, and the second adjacent heat transfer plate on the second side of the heat transfer plate. do. The longitudinal and transverse center axes of the heat transfer plates extending parallel to the central extension plane and perpendicular to each other define the first, second, third and fourth plate regions. The first and second plate regions are arranged on the same side with respect to the transverse center axis, and the first and third plate regions are arranged on the same side with respect to the longitudinal center axis. The first, third and fourth plate regions include first, third and fourth guide portions, respectively. In the heat transfer plate, the first and fourth guides, when viewed from the first side of the heat transfer plate, protrude past the first plane and engage the first adjacent heat transfer plate for alignment of the heat transfer plate and the first adjacent heat transfer plate And a male recess arranged to engage the second adjacent heat transfer plate for alignment of the heat transfer plate and the second adjacent heat transfer plate, as viewed from the second side of the heat transfer plate, respectively. In addition, the third guide portion, when viewed from the second side of the heat transfer plate, protrudes past the second plane and is arranged with a male protrusion arranged to engage the second adjacent heat transfer plate for alignment of the heat transfer plate and the second adjacent heat transfer plate, When viewed from the first side of the heat transfer plate, it comprises a female recess arranged to engage the first adjacent heat transfer plate for alignment of the heat transfer plate and the first adjacent heat transfer plate.

The first and second sides of the heat transfer plate may also be referred to as front and back.

The central extension plane may be arranged in the middle between the first and second planes.

The longitudinal center axis may extend along the opposite long side of the heat transfer plate, while the transverse center axis may extend along the opposite short side of the heat transfer plate.

The edge portion may be an inner edge portion such as an outer circumferential edge portion of the heat transfer plate or an edge portion defining a port hole of the heat transfer plate. Further, only the complete edge portion or only one or more portions thereof may include wrinkles. The wrinkles may be distributed uniformly or non-uniformly along the edges, and all may or may not look the same. The edge portion may include additional corrugations extending in or out of the first and second planes.

Wrinkles form ridges and valleys that may impart a wavy design to the edge. When viewed from the first side of the plate, when the heat transfer plate is arranged in the plate heat exchanger, the ridges are arranged to abut the first adjacent plate, while the valleys are arranged to abut the second adjacent heat transfer plate.

The heat transfer plates may be essentially rectangular, and the longitudinal and transverse center axes may be essentially perpendicular to each other to define four essentially rectangular plate regions.

 "When viewed from the first side of the heat transfer plate" means a case where the first side of the heat transfer plate is viewed at a distance. Similarly, "when viewed from the second side of the heat transfer plate" refers to the case where the second side of the heat transfer plate is viewed at a distance.

Both the heat transfer plate and the first and second adjacent heat transfer plates may be of the same type. Alternatively, the heat transfer plate and the first and second adjacent heat transfer plates may be of different types. For example, both the heat transfer plate and the first and second adjacent heat transfer plates may include guides as defined in the claims, but may be designed differently.

The above-described configuration of the guide portion may enable alignment of the heat transfer plate and the adjacent heat transfer plate regardless of whether the adjacent heat transfer plate is rotated or flipped relative to the heat transfer plate. In addition, alignment of the heat transfer plate and the adjacent heat transfer plate by at least two guides of the heat transfer plate may be possible, which improves the alignment. Moreover, the alignment of the heat transfer plate and the two adjacent heat transfer plates by each of the at least two guide portions of the heat transfer plate, for example the first and second adjacent heat transfer plates described above, may be possible, which improves the alignment. Alignability is naturally dependent on the design of the adjacent heat transfer plate (s).

The second plate area, when viewed from the second side of the heat transfer plate, protrudes beyond the second plane and is arranged with a male protrusion arranged to engage the second adjacent heat transfer plate for alignment of the heat transfer plate and the second adjacent heat transfer plate, and heat transfer When viewed from the first side of the plate, it may also include a second guide comprising a female recess arranged to engage a first adjacent heat transfer plate for alignment of the heat transfer plate and the first adjacent heat transfer plate. Thereby, it may be possible to align the heat transfer plate and the adjacent heat transfer plate by all the guide portions of the heat transfer plate, which improves the alignment. Moreover, it may be possible to align the heat transfer plate and the two adjacent heat transfer plates by each of all the guides of the heat transfer plate, for example the first and second adjacent heat transfer plates described above, which improves the alignment. In addition, alignment is naturally dependent on the design of the adjacent heat transfer plate (s).

The tops of each of the male and female guide protrusions may extend from a transverse center axis to a distance ML1 to a distance ML2 and from a longitudinal center axis to a distance MW1 to a distance MW2. , Each opening or root of the female recess of the third and fourth guides is a distance (F1) from a distance from the central center axis to a distance (FL1) and a distance from the longitudinal center axis (FW1) FW2), FL1 <ML1 <ML2 <FL2, and FW1 <MW1 <MW2 <FW2. Further, the male and female projections (each) of the first and second guides may be fitted to the female recesses (each) of the third and fourth guides. "Fit-fit" means that the male projection can be at least partially accommodated in the female recess. For example, the male protrusions can have an outer circumference that is smaller than the inner circumference of the female recess, and / or the outer surface of the male projection can form a volume smaller than the volume formed by the inner surface of the female recess. Naturally, it is irrelevant to accommodate the male projections of the heat transfer plate in the female recess of the same heat transfer plate and it is impossible without deforming or cutting the heat transfer plate. However, this embodiment inserts the male and female projections of the first and second guides of the heat transfer plate into the female recesses of the third and fourth guides of the first and second adjacent heat transfer plates, and the third and third of the heat transfer plate. 4 By receiving male projections of the first and second guides of the first and second adjacent heat transfer plates by the female recess of the guide, at least a guide of the same type as the heat transfer plate and the heat transfer plate or as defined above It is also possible to enable alignment of the first and second adjacent heat transfer plates.

The respective tops of the male projections of the third and fourth guides may extend from the transverse center axis to a distance ML3 to distance ML4, and from the longitudinal center axis to a distance MW3 to a distance MW4. , Each opening or route of the female recess of the first and second guides is from the center axis transverse to the distance FL3 to the distance FL4, and from the longitudinal center axis to the distance FW3 to the distance FW4. It may be extended, FL3 <ML3 <ML4 <FL4, and FW3 <MW3 <MW4 <FW4. Further, the male and female projections (each) of the third and fourth guides may be fitted to the female recesses (each) of the first and second guides. The meaning of "fit" is as defined above. This embodiment inserts the male and female projections of the third and fourth guide portions of the heat transfer plate into the female recesses of the first and second guide portions of the first and second adjacent heat transfer plates, and the first and second guides of the heat transfer plate. By receiving the male projections of the third and fourth guides of the first and second adjacent heat transfer plates by the negative female recesses, the first comprising at least the same type as the heat transfer plate and the heat transfer plate or as defined above. And alignment of the second adjacent heat transfer plate.

The first and fourth guide portions may extend between the outer edge of the heat transfer plate and the male projection, or even surround the male projection, and may each include a first planar portion extending parallel to the central extension plane. In addition, the second and third guide portions may extend between the outer edge of the heat transfer plate and the male projection, or even surround the male projection, and may each include a second planar portion extending parallel to the central extension plane. This embodiment excludes the arrangement of the male projections at the outer edge of the heat transfer plate, which may improve the stability of the guide.

Similarly, the first and fourth guides may each include a second planar portion extending between the outer edge of the heat transfer plate and the female recess, or even surrounding the female recess, and extending parallel to the central extension plane. The second and third guides may include a first planar portion extending between the outer edge of the heat transfer plate and the female recess, or even surrounding the female recess, and extending parallel to the central extension plane. . This embodiment excludes the arrangement of the female recess at the outer edge of the heat transfer plate, which may improve the stability of the guide.

The first and second planar portions described above may extend in different planes. For example, they may extend into the first and second planes of the heat transfer plate, respectively. In addition, the first and second planar portions may be arranged to abut the first and second adjacent heat transfer plates, respectively, which may improve the stability of the guide portion.

Each first planar portion of the first, second, third and fourth guide portions may be “branched” towards the outer edge of the heat transfer plate to at least partially surround each third planar portion extending into the second plane. have.

In the heat transfer plate, when viewed from the first side of the heat transfer plate, two reinforcing recesses are arranged on each side of the first planar portion with respect to the first planar portion, and with the second planar portion, two reinforcing protrusions are provided It may be configured to be arranged on each side of each of the two flat parts. The reinforcing recesses and protrusions may be arranged continuously along the outer edge of the heat transfer plate. As implied by the name, the reinforcement recesses and protrusions are arranged to reinforce and strengthen the heat transfer plate, such that the guides of the heat transfer plate are first and second adjacent heat transfers, which can negatively affect the alignment of the three heat transfer plates. Reduces the risk of deformation when engaging the plate. The bottom of the reinforcement recess may extend in the second plane, while the top of the reinforcement protrusion may extend in the first plane. In addition, the reinforcing recesses and protrusions may be arranged to abut the first and second adjacent heat transfer plates, respectively, which may improve the stability of the guide. For example, the one or more reinforcing recesses and protrusions can each include one of the folds at the edge of the heat transfer plate.

The first, second, third and fourth guides may be arranged at each one of the four corners of the heat transfer plate. And, the guides may be arranged as far apart from each other as possible and suitable, which may result in an optimized alignment between the heat transfer plates and the first and second adjacent heat transfer plates.

The heat transfer plate may include two opposing long sides extending parallel to the longitudinal center axis and two opposing short sides extending parallel to the transverse center axis. Within each of the first, second, third and fourth guides, the female recesses and the male protrusions are arranged on both sides of an imaginary straight line extending at an angle of 45 degrees to one of the long and short sides of the heat transfer plate. It may be. This may result in an optimized alignment between the heat transfer plate and the first and second adjacent heat transfer plates.

The heat transfer plate is "the depth of the female recess of the third and fourth guides ≥ the height of the male projections of the first and second guides" and "the depth of the female recess of the first and second guides ≥ third and fourth It may be designed to be "height of the male projection of the guide." This embodiment may be accommodated within the recesses of the first and second adjacent heat transfer plates, wherein the complete male projection of the heat transfer plate comprises at least a guide of the same type or as defined above with the heat transfer plate, and the female type of the heat transfer plate. It may also be possible for the seth to fully receive the male projections of the first and second adjacent heat transfer plates. As a result, this allows optimized alignment between the heat transfer plate and the first and second adjacent heat transfer plates.

At least one of the male projections of the first and second guides and at least one of the female recesses of the third and fourth guides may have at least partially uniform cross-sections parallel to the central extension plane. Similarly, at least one of the female recesses of the first and second guides and at least one of the male and female projections of the third and fourth guides may have at least partially uniform cross-sections parallel to the central extension plane. Thereby, a good fit may be possible between the male recess and the male projections of the first and second adjacent heat transfer plates which include at least a guide of the same type as the heat transfer plate and the heat transfer plate or as defined above.

At least one of the male and female guides of the first and second guides and at least one of the female recesses of the third and fourth guides are parallel to the central extension plane, each comprising two right-angled parts, ie two parts perpendicular to each other. It may have a cross section. Similarly, at least one of the female recesses of the first and second guides and at least one of the male and female projections of the third and fourth guides may have a cross section parallel to the central extension plane, each comprising two right-angled portions, respectively. . Thereby, alignment of the first and second adjacent heat transfer plates in at least two orthogonal directions, ie optimal alignment, of at least the same type as the heat transfer plate and the heat transfer plate or at least as defined above, may be possible.

The plate pack for a heat exchanger according to the present invention includes first, second and third heat transfer plates as described above, which may or may not be similar. The second heat transfer plate is arranged between the first and third heat transfer plates. The first and second sides of the second heat transfer plate abut the first side of the second and third heat transfer plates of the first heat transfer plate, respectively, and the second heat transfer plate is relative to the first and third heat transfer plates, When the second heat transfer plate is rotated 180 degrees about an axis extending parallel to the normal of the center extension plane and through an intersection between the longitudinal and transverse center axes, ie the heat transfer plates are relative to each other with the above definition. When rotated,

The male projections of the first and fourth guide portions of the second heat transfer plate are respectively received in the female recesses of the fourth and first guide portions of the first heat transfer plate,

The male projections of the second and third guide portions of the first heat transfer plate are respectively received in the female recesses of the third and second guide portions of the second heat transfer plate,

The male projections of the fourth and first guide portions of the third heat transfer plate are respectively received in the female recesses of the first and fourth guide portions of the second heat transfer plate,

The male projections of the second and third guide portions of the second heat transfer plate are received in the female recesses of the third and second guide portions of the third heat transfer plate, respectively.

In addition, the first and second surfaces of the second heat transfer plate abut the first surface of the first heat transfer plate and the second surface of the third heat transfer plate, respectively, and the second heat transfer plate is attached to the first and third heat transfer plates. With respect to, when rotated 180 degrees around an axis coincident with the transverse center axis of the second heat transfer plate, that is, when the heat transfer plates are flipped with respect to each other with the above definition,

The male projections of the first and fourth guides of the second heat transfer plate are respectively received in the female recesses of the third and second guides of the first heat transfer plate,

The male projections of the first and fourth guide portions of the first heat transfer plate are respectively received in the female recesses of the third and second guide portions of the second heat transfer plate,

The male projections of the second and third guide portions of the third heat transfer plate are respectively received in the female recesses of the fourth and first guide portions of the second heat transfer plate,

The male projections of the second and third guide portions of the second heat transfer plate are received in the female recesses of the fourth and first guide portions of the third heat transfer plate, respectively.

Other objects, features, aspects and advantages of the present invention will become apparent from the following detailed description and drawings.

Now, the present invention will be described in more detail with reference to the accompanying schematic drawings.
1 is a schematic plan view of a plate pack for a heat transfer plate and a heat exchanger according to the present invention.
FIG. 2A is a schematic plan view of an upper left corner portion of the heat transfer plate of FIG. 1 including a first guide.
FIG. 2B is a schematic plan view of the upper right corner portion of the heat transfer plate of FIG. 1 including a second guide.
FIG. 2C is a schematic plan view of a lower left corner portion of the heat transfer plate of FIG. 1 including a third guide.
2D is a schematic plan view of the lower right corner portion of the heat transfer plate of FIG. 1 including a fourth guide.
3a schematically shows a section AA of the portion of FIG. 2a.
3B schematically shows a cross-section BB of the portion of FIG. 2B.
3c schematically shows a cross-section CC of the portion of FIG. 2c.
3d schematically shows a section DD of the portion of FIG. 2d.
FIG. 3e schematically shows a cross section EE of the portion of FIG. 2d.
3f schematically shows a cross-section FF of the portion of FIG. 2d.
3G schematically shows a cross-section GG of the portion of FIG. 2D.
4A schematically shows a cross section XX of a portion of the plate pack of FIG. 1 with the heat transfer plates rotated relative to each other.
4B schematically shows a cross section YY of a portion of the plate pack of FIG. 1 with the heat transfer plates rotated relative to each other.
4C schematically shows a cross-section ZZ of a portion of the plate pack of FIG. 1 with the heat transfer plates rotated relative to each other.
4D schematically shows a cross-section QQ of a portion of the plate pack of FIG. 1 with the heat transfer plates rotated relative to each other.
5A schematically shows a cross section of a portion of a plate pack corresponding to cross section XX, with the heat transfer plates flipped over each other.
5b schematically shows a cross section of a portion of a plate pack corresponding to cross section YY, with the heat transfer plates inverted relative to each other.
5c schematically shows a cross section of a portion of the plate pack corresponding to cross section ZZ, with the heat transfer plates inverted relative to each other.
Figure 5d schematically shows a cross section of a portion of the plate pack corresponding to the cross section QQ, with the heat transfer plates inverted relative to each other.
FIG. 6 schematically shows a cross section through each outer edge portion parallel to each longitudinal center axis of the heat transfer plate, of the plate pack portion of FIGS. 4A-4D as well as the plate pack portion of FIGS. 5A-5D. .
7 schematically shows an alternative cross section of the female recess or male projection of the guide.

Referring to FIG. 1, there is shown a plate pack 2 for a gasketed plate-type heat exchanger comprising a plurality of heat transfer plates. All heat transfer plates are of the same type. 4A to 4D, which will be further described below, show the first, second and third heat transfer plates 4a, 4b and 4c of the plurality of heat transfer plates, respectively. The first heat transfer plate 4a can also be seen in FIG. 1. The design and function of the gasketed plate type heat exchanger is well known and described in an introductory manner, and will not be described further herein.

From now on, the heat transfer plate 4a will be further described with reference to Figs. 1, 2A to 2D and Figs. 3A to 3G, respectively showing the heat transfer plate and portions and sections of the heat transfer plate, respectively. The heat transfer plate 4a is an essentially rectangular stainless steel sheet having opposing first and second faces 6 and 8, which may also be referred to as front and back respectively. In Fig. 1, only the first face 6 is visible. The heat transfer plate 4a includes two opposing long sides 10 and two opposing short sides 12.

The heat transfer plate is transverse to the longitudinal center axis 20 extending parallel to it in the middle between the long sides 10 and perpendicular to the longitudinal center axis 20 extending parallel to it in the middle between the short sides 12. It further has a central axis 22 (Fig. 1). The longitudinal and transverse center axes divide the heat transfer plate 4a into four equally sized first, second, third and fourth plate regions 24, 26, 28 and 30, respectively. The first and second plate regions 24 and 26 are arranged on the same side with respect to the transverse center axis 22, while the first and third plate regions 24 and 28 are at the longitudinal center axis 20. Against the same side.

The heat transfer plate 4a has four port holes 32 arranged at each one of the four corners 34, 36, 38 and 40 of the heat transfer plate, and each of the short sides 12 of the heat transfer plate 4a. And a recess 42 extending from one and arranged to receive the transport and guide bars of the plate heat exchanger.

The heat transfer plate 4a is pressed in a pressing tool in a conventional manner, providing a desired structure, more specifically, a different corrugation pattern within different parts of the heat transfer plate. The crease pattern is optimized for the specific function of each plate part. Thus, the heat transfer plate 4a includes two distribution regions 44, each of which is provided with a distribution pattern suitable for optimized fluid distribution across the heat transfer plate. In addition, the heat transfer plate 4a includes a heat transfer region 46 arranged between the distribution regions 44 and provided with a heat transfer pattern suitable for optimizing heat transfer between two fluids flowing on both sides of the heat transfer plate. In addition, the heat transfer plate 4a includes an inner edge portion 48 surrounding the port hole 32 and an outer edge portion 50 extending along the outer edge 51 of the heat transfer plate 4a. The inner and outer edge portions 48 and 50 include wrinkles 52 that further strengthen the inner and outer edge portions to better resist the heat transfer plate 4a against deformation. In addition, the corrugation 52 forms a support structure that is arranged to abut the adjacent heat transfer plate when the heat transfer plate 4a is arranged in a plate type heat exchanger. When the heat transfer plates are arranged in a plate heat exchanger, depending on the design of the distribution and heat transfer patterns, the heat transfer plates 4a may be arranged to abut adjacent heat transfer plates in the distribution and heat transfer regions 44 and 46, respectively. However, this will not be described further herein. In addition, the heat transfer plate 4a includes grooves 53 arranged to receive gaskets.

With particular reference to FIGS. 2D, 3E and 3F, the pleats 52 extend between the center extension plane 58 and the first plane 54 and the second plane 56 parallel to the shape plane of FIG. 1. do. The central extension plane 58 extends in the middle between the first and second planes 54 and 56, respectively, and the bottom of the groove 53 extends in the central extension plane, ie the so-called intermediate plane.

The first, second, third and fourth plate regions 24, 26, 28 and 30 are respectively arranged at each one of the four corners 34, 36, 38 and 40 of the heat transfer plate 4a. 1, 2, 3 and 4 guides 60, 62, 64 and 66. With particular reference to FIGS. 2A, 3A, 2D, 3D and 3F, the first and fourth guides 60 and 66, as viewed from the first side 6 of the heat transfer plate 4a, respectively It includes a male projection (68, 70). The male projections 68 and 70 surround each of the male projections 68 and 70 and extend into the first plane 54, each first plane portion of the first and fourth guides 60 and 66 ( 72 and 74). Thus, the male projections 68 and 70 project from the first plane 54 to a third plane 76 arranged on the side opposite to the central extension plane 58 with respect to the first plane 54. In addition, the first and fourth guide portions 60 and 66 include respective female recesses 78 and 80 when viewed from the second surface 8 of the heat transfer plate 4a. Female recesses 78 and 80 surround each female recess 78 and 80 and extend into a second plane 56, each second plane of first and fourth guides 60 and 66 It extends from parts 82 and 84. Thus, the female recesses 78 and 80 extend from the second plane 56 to the fourth plane 86 arranged on the same side as the first plane 54 with respect to the central extension plane 58.

 Similarly, referring specifically to FIGS. 2B, 3B, 2C, and 3C, the second and third guides 62 and 64, when viewed from the second side 8 of the heat transfer plate 4a, Each male protrusion 88, 90 is included. The male protrusions 88 and 90 surround each of the male protrusions 88 and 90 and extend into the second plane 56, each of the second planar portions of the second and third guides 62 and 64 ( 92 and 94). Thus, the male projections 88 and 90 project from the second plane 56 to the fifth plane 96 arranged on the opposite side to the central extension plane 58 with respect to the second plane 56. In addition, the second and third guide portions 62 and 64 include respective female recesses 98 and 100 as viewed from the first side 6 of the heat transfer plate 4a. Female recesses 98 and 100 surround each female recess 98 and 100 and extend into a first plane 54, each first plane of second and third guides 62 and 64 It extends from parts 102 and 104. Thus, the female recesses 102 and 104 extend from the first plane 54 to the sixth plane 106 arranged on the same side as the second plane 56 with respect to the central extension plane 58.

Naturally, the male projection when viewed from one side of the heat transfer plate forms a female recess when viewed from the other side of the plate, and vice versa.

Thus, as apparent from FIGS. 2A, 2B, 2C, and 2D, each of the first, second, third, and fourth guides 60, 62, 64, and 66 includes male protrusions and female recesses. Within each of the first, second, third and fourth guides, the female recess and the male projection are long sides that delimit each one of the corners from each one of the corners 34, 36, 38 and 40 And an imaginary straight line 108 extending at an angle of 45 degrees with respect to the short side.

The male projections 68, 70, 88 and 90, parallel to the central extension plane 58, and the female recesses 78, 80, 98 and 100 all have essentially uniform rectangular cross-sections, and The cross section is larger than the cross section of the male protrusion. All female recesses have essentially the same cross section, and all male protrusions have essentially the same cross section. Thus, the male projection fits into the female recess. Also, all female recesses have essentially the same height (d), all male projections have essentially the same depth (h), and d is essentially equal to h. The depth d and height h of the female recess 78 and the male projection 68 of the first guide 60 are shown in FIG. 2A.

As shown in FIG. 1 in combination with FIGS. 2A, 2B, 2C, and 2D, each opening 78 'of the female recesses 78 and 98 of the first and second guides 60 and 62 and 98 ') extends from the transverse center axis 22 to a distance FL3 to a distance FL4, and from the longitudinal center axis 20 to a distance FW3 to a distance FW4, respectively. Further, the tops 90 'and 70' of the male projections 90 and 70 of the third and fourth guides 64 and 66 are from the transverse center axis 22 to the distance ML3 to the distance ML4. And, it extends from the longitudinal center axis 20 to the distance (MW4) from the distance (MW3), respectively. FL3 <ML3 <ML4 <FL4, and FW3 <MW3 <MW4 <FW4. Further, the tops 68 'and 88' of the male protrusions 68 and 88 of the first and second guides 60 and 62 are from the transverse center axis 22 to the distance ML1 to the distance ML2. And, from the longitudinal center axis 20 to the distance MW2 from the distance MW1. Further, the openings 100 'and 80' of the female recesses 100 and 80 of the third and fourth guides 64 and 66 are the distance FL2 from the distance FL1 from the transverse center axis 22. To and from the longitudinal center axis 20 to a distance FW2 from a distance FW1, respectively. FL1 <ML1 <ML2 <FL2, and FW1 <MW1 <MW2 <FW2.

With particular reference to FIGS. 2A, 2B, 2C, 2D, 3E, 3F and 3G, first, first, to strengthen the edges 34, 36, 38 and 40 of the heat transfer plate 4a Each of the first planar portions 72, 102, 104 and 74 of the second, third and fourth guides 60, 62, 64 and 66 is directed toward the outer edge 51 of the heat transfer plate 4a, respectively. Branched, and partially encloses the third planar portions 110 ', 112', 114 'and 116', which extend into the second plane 56, respectively. More specifically, the first planar portions 72, 102, 104 and 74 have first reinforcement protrusions 72 ', 102', 104 on each one side of the second planar portions 82, 92, 94 and 84. 'And 74'), respectively. Each adjacent one of the pleats 52 on the other opposing side of the second planar portions 82, 92, 94 and 84 forms second reinforcement protrusions 52A, 52B, 52C and 52D. Each of the third planar portions 110 ', 112', 114 'and 116', each of the first reinforcement recesses arranged on one side of each of the first planar portions 72, 102, 104 and 74 ( 110, 112, 114 and 116). Each closest one of the pleats 52 on the other opposing side of the first planar portions 72, 102, 104 and 74 forms second reinforcement recesses 52a, 52b, 52c and 52d.

4A-4D show cross-sections of the first, second and third heat transfer plates 4a, 4b and 4c of the plate pack 2 of FIG. 1. The second heat transfer plate 4b is arranged between the first and third heat transfer plates 4a and 4c. Further, the second heat transfer plate 4b is perpendicular to the transverse and longitudinal center axes 20 and 22 with respect to the first and third heat transfer plates 4a and 4c and extends through the intersection between these axes. It is rotated 180 degrees around the axis. Thereby, the first and second surfaces 6 and 8 of the second heat transfer plate 4b are respectively the first surface of the second surface 8 and the third heat transfer plate 4c of the first heat transfer plate 4a. (6). More specifically, the portion extending to the first plane 54 of the second heat transfer plate 4b contacts the opposing portion extending to the second plane 56 of the first heat transfer plate 4a, and the second heat transfer plate The portion extending to the second plane 56 of (4b) contacts the opposing portion extending to the first plane 54 of the third heat transfer plate 4c. For example, as shown schematically in FIG. 6 with respect to the outer edge portions of the heat transfer plates 4a, 4b and 4c, the inner and outer edge portions 48, 50 of the second heat transfer plate 4b (FIG. 1) ) Corrugations 52 of the inner and outer edge portions 48 of the first and third heat transfer plates 4a and 4c, respectively, on the first side 6 and the second side 8 of the second heat transfer plate 4b And 50). In addition, the first reinforcing protrusions 72 ', 102', 104 ', 74' of the second heat transfer plate 4b and the third planar portions 110 ', 112', 114 ', 116' are the first heat transfer plates. Partial with the third planar portions 116 ', 114', 112 ', 110' of (4a) and the first reinforcing protrusions 74 ', 104', 102 ', 72' of the third heat transfer plate 4c, respectively. Touches.

Further, the fourth guide portion 66 of the second heat transfer plate 4b is engaged with the first guide portion 60 of the first and third heat transfer plates 4a and 4c (FIG. 4A). More specifically, the male projection 70 of the second heat transfer plate 4b is received in the female recess 78 of the first heat transfer plate 4a, and the first flat portion 74 of the second heat transfer plate 4b ) Abuts the second flat portion 82 of the first heat transfer plate 4a. In addition, the male projection 68 of the third heat transfer plate 4c is received in the female recess 80 of the second heat transfer plate 4b, and the first flat portion 72 of the third heat transfer plate 4c is It is in contact with the second flat portion 84 of the second heat transfer plate 4b.

In addition, the third guide portion 64 of the second heat transfer plate 4b is engaged with the second guide portion 62 of the first and third heat transfer plates 4a and 4c (FIG. 4B). More specifically, the male projection 88 of the first heat transfer plate 4a is received in the female recess 100 of the second heat transfer plate 4b, and the second flat portion 92 of the first heat transfer plate 4a ) Abuts the first flat portion 104 of the second heat transfer plate 4b. In addition, the male projection 90 of the second heat transfer plate 4b is received in the female recess 98 of the third heat transfer plate 4c, and the second flat portion 94 of the second heat transfer plate 4b is It is in contact with the first flat portion 102 of the third heat transfer plate 4c.

Further, the second guide portion 62 of the second heat transfer plate 4b engages the third guide portion 64 of the first and third heat transfer plates 4a and 4c (FIG. 4C). More specifically, the male projection 90 of the first heat transfer plate 4a is received in the female recess 98 of the second heat transfer plate 4b, and the second flat portion 94 of the first heat transfer plate 4a ) Abuts the first flat portion 102 of the second heat transfer plate 4b. In addition, the male projection 88 of the second heat transfer plate 4b is received in the female recess 100 of the third heat transfer plate 4c, and the second flat portion 92 of the second heat transfer plate 4b is It is in contact with the first flat portion 104 of the third heat transfer plate 4c.

Further, the first guide portion 60 of the second heat transfer plate 4b engages the fourth guide portion 66 of the first and third heat transfer plates 4a and 4c (FIG. 4D). More specifically, the male projection 68 of the second heat transfer plate 4b is received in the female recess 80 of the first heat transfer plate 4a, and the first flat portion 72 of the second heat transfer plate 4b ) Abuts the second flat portion 84 of the first heat transfer plate 4a. In addition, the male projection 70 of the third heat transfer plate 4c is received in the female recess 78 of the second heat transfer plate 4b, and the first flat portion 74 of the third heat transfer plate 4c is It is in contact with the second flat portion 82 of the second heat transfer plate 4b.

Thereby, in the plate pack 2, the second heat transfer plate 4b, in all four guides 60, 62, 64 and 66, is formed with all of the first and third heat transfer plates 4a, 4c. Engagement, which results in reliable and effective alignment of the first, second and third heat transfer plates.

In the plate pack 2 described above, the heat transfer plates are "rotated" with respect to each other. In an alternative plate pack according to the invention, the heat transfer plates instead are “inverted” relative to each other. Thus, the second heat transfer plate 4b is arranged between the first and third heat transfer plates 4a and 4c. Further, both the first and third heat transfer plates 4a and 4b are rotated 180 degrees around each transverse center axis 22 with respect to the second heat transfer plate 4b. Thereby, the first and second surfaces 6 and 8 of the second heat transfer plate 4b are respectively the first surface 6 of the first heat transfer plate 4a and the second surface of the third heat transfer plate 4c. (8). More specifically, the portion extending to the first plane 54 of the second heat transfer plate 4b contacts the opposing portion extending to the first plane 54 of the first heat transfer plate 4a, and the second heat transfer plate The portion extending to the second plane 56 of (4b) contacts the opposing portion extending to the second plane 56 of the third heat transfer plate 4c. For example, as shown schematically in FIG. 6 with respect to the outer edge portions of the heat transfer plates 4a, 4b and 4c, the inner and outer edge portions 48, 50 of the second heat transfer plate 4b (FIG. 1) ) Corrugations 52 of the inner and outer edge portions 48 of the first and third heat transfer plates 4a and 4c, respectively, on the first side 6 and the second side 8 of the second heat transfer plate 4b And 50). In addition, the first reinforcing protrusions 72 ', 102', 104 ', 74' of the second heat transfer plate 4b and the third planar portions 110 ', 112', 114 ', 116' are the first heat transfer plates. Partially with the first reinforcing protrusions 104 ', 74', 72 ', 102' of (4a) and the third flat portions 114 ', 116', 110 ', 112' of the third heat transfer plate 4c, respectively. Touches.

Further, the third guide portion 64 of the second heat transfer plate 4b is engaged with the first guide portion 60 of the first and third heat transfer plates 4a and 4c (FIG. 5A). More specifically, the male projection 68 of the first heat transfer plate 4a is received in the female recess 100 of the second heat transfer plate 4b, and the first flat portion 72 of the first heat transfer plate 4a ) Abuts the first flat portion 104 of the second heat transfer plate 4b. In addition, the male projection 90 of the second heat transfer plate 4b is received in the female recess 78 of the third heat transfer plate 4c, and the second flat portion 94 of the second heat transfer plate 4b is It is in contact with the second flat portion 82 of the third heat transfer plate 4c.

Further, the fourth guide portion 66 of the second heat transfer plate 4b engages the second guide portion 62 of the first and third heat transfer plates 4a and 4c (FIG. 5B). More specifically, the male projection 70 of the second heat transfer plate 4b is received in the female recess 98 of the first heat transfer plate 4a, and the first flat portion 74 of the second heat transfer plate 4b ) Abuts the first flat portion 102 of the first heat transfer plate 4a. In addition, the male projection 88 of the third heat transfer plate 4c is received in the female recess 80 of the second heat transfer plate 4b, and the second flat portion 92 of the third heat transfer plate 4c is It is in contact with the second flat portion 84 of the second heat transfer plate 4b.

In addition, the first guide portion 60 of the second heat transfer plate 4b is engaged with the third guide portion 64 of the first and third heat transfer plates 4a and 4c (FIG. 5C). More specifically, the male projection 68 of the second heat transfer plate 4b is received in the female recess 100 of the first heat transfer plate 4a, and the first flat portion 72 of the second heat transfer plate 4b ) Abuts the first flat portion 104 of the first heat transfer plate 4a. In addition, the male projection 90 of the third heat transfer plate 4c is received in the female recess 78 of the second heat transfer plate 4b, and the second flat portion 94 of the third heat transfer plate 4c is It is in contact with the second flat portion 82 of the second heat transfer plate 4b.

Further, the second guide portion 62 of the second heat transfer plate 4b engages the fourth guide portion 66 of the first and third heat transfer plates 4a and 4c (FIG. 5D). More specifically, the male projection 70 of the first heat transfer plate 4a is received in the female recess 98 of the second heat transfer plate 4b, and the first flat portion 74 of the first heat transfer plate 4a ) Abuts the first flat portion 102 of the second heat transfer plate 4b. In addition, the male projection 88 of the second heat transfer plate 4b is received in the female recess 80 of the third heat transfer plate 4c, and the second flat portion 92 of the second heat transfer plate 4b is It is in contact with the second flat portion 84 of the third heat transfer plate 4c.

Thereby, in the plate pack described above, the second heat transfer plate 4b fits all of the first and third heat transfer plates 4a, 4c in all four guides 60, 62, 64 and 66. Bite, which results in reliable and effective alignment of the first, second and third heat transfer plates.

Thus, due to the unique construction of the first, second, third and fourth guides 60, 62, 64 and 66, the heat transfer plates 4a, 4b and 4c are rotated or flipped relative to each other. Without plate, they are properly aligned with each other. Due to the design and position on the heat transfer plate of the female recess and the male protrusion, the actual alignment of the heat transfer plate is the female recess and the male part facing the outer part of the female recess and the heat transfer plate, each outer edge 51 of the heat transfer plate. It is carried out by the part of the protrusion. Thus, when the heat transfer plate is aligned, the outer portions of the female recess and the male projection of one heat transfer plate engage with the outer portions of the male projection and the female recess of the adjacent plate, respectively. The inner portion of the female recess and the male projection, ie the portion of the female recess and the male projection, which deviates from each outer edge 51 of the heat transfer plate, is not engaged with each other.

The first and second flat portions 72, 74, 102, 104 and 82, 84, 92, 94 extend into the first and second planes 54 and 56, and the female recesses 78, 80, 98 and The depth of 100) is equal to the height of the male projections 68, 70, 88 and 90, and like the inner bottom surface of the female recess and the outer top surface of the male projection, the first and second plate portions are in the plate pack. Will make the plate pack more stable by touching each other.

The above-described embodiment of the present invention should be seen only as an example. Those skilled in the art recognize that the described embodiments can be modified and combined in various ways without departing from the concept of the invention.

For example, the female recess and the male projection need not have a rectangular cross section. By way of example, they may have a curved, triangular or pentagonal cross section, such as the cross section shown in FIG. 7, forming two right angles and including two outer portions 118 and 120 perpendicular to each other for optimal heat transfer plate alignment. . Since the alignment function is within the outer portions 118 and 120, the inner portion can be cut or shortened to enable space-efficient female recesses and male protrusions while increasing alignment capability.

Further, it is not necessary that all of the female recesses have the same cross section and the same depth. Similarly, the male protrusions need not all have the same cross section and the same height. Also, the depth of the female recess need not be the same as the height of the male projection, and may be deeper or shallower. Also, the one or more first planar portions of the guide portion may extend in a plane different from the first plane. Similarly, the one or more second planar portions of the guide portion may extend in a different plane than the second plane.

Further, the alignment function need not be only within the outer portion of the female recess and the male projection, instead only within the inner portion of the female recess and the male projection, or one or more outer portions of the female recess and the male projection and / or Or it can be in one or more internal parts.

The heat transfer plate need not be rectangular and may have other shapes, such as essentially rectangular, round or oval, with curved edges instead of right angled edges. The heat transfer plate need not be made of stainless steel, but can be other materials such as titanium or aluminum.

The guide portion of the heat transfer plate need not be arranged at each edge of the heat transfer plate, but can be arranged closer to the longitudinal center axis and / or closer to the transverse center axis. Also, within each guide, the female recess and the male projection need not be arranged on both sides, but instead on the same side of the imaginary straight line 108 shown in FIGS. 2A, 2B, 2C and 2D. Can be arranged. Further, the distance between the female recess and the male projection of each guide can be changed. Typically, the female recesses and the male protrusions are arranged where there is space available on the heat transfer plate, for example in the center of the short side and / or the edge close to the outer edge of the heat transfer plate.

The plate pack described above contains only one plate type. Naturally, the plate pack may instead comprise two or more different types of alternately arranged heat transfer plates, for example heat transfer plates having different heat transfer patterns and / or guides as long as the heat transfer patterns and / or guides are compatible.

The present invention is of a type other than gasketed, such as plate-type heat exchangers, such as light welded, fully welded, and semi-welded (heat transfer plates are welded in pairs to each other in a cassette, which are separated by a gasket). It can be used in connection with a plate type heat exchanger. In addition, the present invention can be used with plate-type heat exchangers without transport and guide bars, i.e., heat transfer plates without recesses for receiving such transport and guide bars.

The positions of the first, second, center extension, third, fourth, fifth and sixth planes 54, 56, 58, 76, 86, 96 and 106 need not be as defined above but may be changed. have. As an example, referring to FIGS. 3A, 3D and 4A, the fourth plane 86 may instead extend between the second plane 56 and the central extension plane 58, and the third plane 76 Can eventually extend closer to the first plane 54. As another example, the fourth plane 86 can instead extend between the first plane 54 and the third plane 76, and the third plane 76 is consequently further from the first plane 54. It can be extended far.

It should be emphasized that the description of details not related to the present invention has been omitted and the drawings are only schematic and not to scale. It should also be noted that some of the drawings have been simplified more than others. Accordingly, some components may be shown in one drawing, but may be omitted in another drawing.

Claims (15)

Heat transfer plates (4a, 4b, 4c),
The opposing first and second faces 6, 8 have an outer edge 51 and a central extension plane 58, and include edge portions 48, 50 including a corrugation 52, the corrugation being central It extends between the first and second planes 54, 56 parallel to the extension plane, the central extension plane 58 is arranged between the first and second planes 54, 56, and the corrugation 52 is, When the heat transfer plate is arranged in a plate-type heat exchanger, it is in contact with the second adjacent heat transfer plate in the first side 6 of the heat transfer plate, in contact with the first adjacent heat transfer plate, and in the second side 8 of the heat transfer plate. The longitudinal and transverse center axes 20, 22 of the heat transfer plates, which are arranged to abut, extend parallel to the central extension plane 58 and are perpendicular to each other, are the first, second, third and fourth plate regions 24 , 26, 28, 30), and the first and second plate regions 24, 26 are arranged on the same side with respect to the transverse center axis 22, The first and third plate regions 24 and 28 are arranged on the same side with respect to the longitudinal center axis 20, and the first, third and fourth plate regions 24, 28 and 30 are first and third. In the heat transfer plate, which includes the third and fourth guide portions 60, 64, 66, respectively, the first and fourth guide portions 60, 66, when viewed from the first side 6 of the heat transfer plate, Male projections 68, 70 arranged to engage the first adjacent heat transfer plate for alignment of the heat transfer plate and the first adjacent heat transfer plate and projecting past the first plane 54, and the second side 8 of the heat transfer plate As seen in, for the alignment of the heat transfer plate and the second adjacent heat transfer plate, each includes female recesses 78 and 80 arranged to engage with the second adjacent heat transfer plate, and the third guide portion 64 includes a heat transfer plate When viewed from the second side 8 of the, it projects beyond the second plane 56 and the heat transfer plate and the second adjacent heat transfer plate A male protrusion 90 arranged to engage a second adjacent heat transfer plate for alignment, and a first adjacent heat transfer plate for alignment of the heat transfer plate and the first adjacent heat transfer plate as viewed from the first side 6 of the heat transfer plate A heat transfer plate (4a, 4b, 4c), comprising a female recess (100) arranged to engage with. The second plate area (26) comprises a second guide portion (62), and the second guide portion, when viewed from the second surface (8) of the heat transfer plate, the second plane (56) A male protrusion 88 arranged to engage the second adjacent heat transfer plate for alignment of the heat transfer plate and the second adjacent heat transfer plate and projecting past and as seen from the first side 6 of the heat transfer plate, the heat transfer plate and the first A heat transfer plate (4a, 4b, 4c), comprising a female recess (98) arranged to engage a first adjacent heat transfer plate for alignment of adjacent heat transfer plates. 3. The method of claim 2, wherein the tops (68 ', 88') of the male projections (68, 88) of the first and second guides (60, 62) are at a distance (ML1) from the transverse center axis (22). Openings of the female recesses 100, 80 of the third and fourth guides 64, 66, extending to the ML2 and from the longitudinal center axis 20 to the distance MW2 at the distance MW1. (100 ', 80') extends from the transverse center axis 22 to a distance FL1 to a distance FL2, and from the longitudinal center axis 20 to a distance FW1 to a distance FW2, FL1 <ML1 <ML2 <FL2 and FW1 <MW1 <MW2 <FW2, and the male protrusions 68 and 88 of the first and second guides 60 and 62 are of the third and fourth guides 64 and 66. Heat transfer plates 4a, 4b, 4c, fitted to female recesses 100, 80. The top (90 ', 70') of the male projections (90, 70) of the third and fourth guides (64, 66) is a distance from the transverse center axis (22) according to claim 2 or 3 ( ML3) to distance ML4, and from longitudinal center axis 20 to distance MW3 to distance MW4, female recesses 78 of the first and second guides 60, 62, The openings 78 'and 98' of 98 are from the transverse center axis 22 to the distance FL3 to the distance FL4, and from the longitudinal center axis 20 to the distance FW3 to the distance FW4. Extended, FL3 <ML3 <ML4 <FL4 and FW3 <MW3 <MW4 <FW4, and the male projections 90, 70 of the third and fourth guides 64, 66 are the first and second guides 60 , 62) fitted to female recesses 78, 80 of heat transfer plates 4a, 4b, 4c. 5. The central extension plane (58) according to claim 2, wherein the first and fourth guides (60, 66) are between the outer edge (51) of the heat transfer plate and the male protrusions (68, 70). ), The first planar portions 72, 74 extending parallel to each other, and the second and third guide portions 62, 64 between the outer edge 51 and the male projections 80, 90 of the heat transfer plate In the heat transfer plate (4a, 4b, 4c), each comprising a second plane portion (92, 94) extending parallel to the central extension plane (58). 6. The center extension plane (6) according to any one of claims 2 to 5, wherein the first and fourth guides (60, 66) are provided between the outer edge (51) of the heat transfer plate and the female recesses (78, 80). 58, the second planar portions 82, 84 extending parallel to each other, and the second and third guide portions 62, 64, the outer edge 51 of the heat transfer plate and the female recesses 98, 100 ) Between the first flat portions 102, 104, which extend parallel to the central extension plane 58, respectively, heat transfer plates 4a, 4b, 4c. 7. The method of claim 5 or 6, wherein the first and second planar portions (72, 74, 102, 104, 82, 84, 92, 94) are the first and second planes (54, 56) of the heat transfer plate. Heat transfer plates 4a, 4b, 4c, each extending. 8. Reinforcement recesses (110, 1) according to any one of claims 5 to 7, wherein the first planar portions (72, 102, 104, 74) have two reinforcing recesses (110, as seen from the first side (6) of the heat transfer plate 52a, 112, 52b, 114, 52c, 116, 52d) are arranged on each side of each of the first flat portions, and with respect to the second flat portions 82, 92, 94, 84, two reinforcing protrusions 72 ', Heat transfer plates 4a, 4b, 4c, wherein 52A, 102 ', 52B, 104', 52C, 74 ', 52D) are arranged on each side of each of the second planar portions. 9. The method of any one of claims 2-8, wherein the first, second, third and fourth guides (60, 62, 64, 66) have four corners (34, 36, 38, Heat transfer plates 4a, 4b, 4c, arranged on each one of 40). 10. The method of any one of claims 2-9, wherein two opposing long sides (10) extend parallel to the longitudinal center axis (20) and two opposing sides extend parallel to the transverse center axis (22). The short side 12, and within each of the first, second, third and fourth guides 60, 62, 64, 66, female recesses 78, 80, 98, 100 and The male projections 68, 70, 88, 90 are arranged on both sides of an imaginary straight line 108 extending at an angle of 45 degrees to one of the long sides 10 and one of the short sides 12 of the heat transfer plate. (4a, 4b, 4c). The depth (d) of the third and fourth guides (64, 66) of the female recess (100, 80) ≥ first and second guides (60) according to any one of claims 2 to 10 , 62) is the height (h) of the male projections 68, 88, and the depth d of the female recesses 78, 98 of the first and second guides 60, 62 ≥ third and fourth Heat transfer plates 4a, 4b, 4c, which are the height h of the male projections 90, 70 of the guides 64, 66. 12. At least one of the male and female projections (68, 88) of the first and second guides (60, 62) and the third and fourth guides (64, 66) according to any one of claims 2-11. At least one of the female recesses 100 and 80 has a at least partially uniform cross section parallel to the central extension plane 58, the female recesses 78 of the first and second guides 60 and 62, At least one of 98) and at least one of the male projections 90, 70 of the third and fourth guides 64, 66 have a at least partially uniform cross section parallel to the central extension plane 58. (4a, 4b, 4c). 13. A method according to any one of claims 2 to 12, wherein at least one of the male and female projections (68, 88) of the first and second guides (60, 62) and the third and fourth guides (64, 66) are provided. At least one of the female recesses 100, 80 of the heat transfer plates 4a, 4b, 4c having a cross section parallel to the central extension plane 58, each comprising two right angled portions. 14. The method of any one of claims 2-13, wherein at least one of the female recesses (78, 98) of the first and second guides (60, 62) and the third and fourth guides (64, 66) ) At least one of the male projections 90, 70 of the heat transfer plates 4a, 4b, 4c having a cross section parallel to the central extension plane 58, each comprising two right-angled portions. Plate pack for heat exchanger (2),
The first, second and third heat transfer plates (4a, 4b, 4c) according to any one of claims 2 to 14, the second heat transfer plate (4b) is the first and third heat transfer plates ( 4a, 4c),
The first and second surfaces 6 and 8 of the second heat transfer plate 4b are in contact with the first surface 6 of the second surface 8 and the third heat transfer plate 4c of the first heat transfer plate 4a. Respectively, and the second heat transfer plate 4b is parallel to and perpendicular to the normal of the center extension plane 58 of the second heat transfer plate 4b with respect to the first and third heat transfer plates 4a, 4c. When rotated 180 degrees around an axis extending through the intersection between the directional and transverse center axes 20, 22,
The male and female projections 68 and 70 of the first and fourth guides 60 and 66 of the second heat transfer plate 4b are of the fourth and first guides 66 and 60 of the first heat transfer plate 4a. Housed in female recesses 80 and 78, respectively
The male projections 88 and 90 of the second and third guides 62 and 64 of the first heat transfer plate 4a are of the third and second guides 64 and 62 of the second heat transfer plate 4b. Accommodated in female recesses 100 and 98, respectively
The male and female projections 70 and 68 of the fourth and first guides 66 and 60 of the third heat transfer plate 4c are of the first and fourth guides 60 and 66 of the second heat transfer plate 4b. Accommodated in female recesses 78 and 80, respectively
The male projections 88 and 90 of the second and third guides 62 and 64 of the second heat transfer plate 4b are of the third and second guides 64 and 62 of the third heat transfer plate 4c. Accommodated in female recesses 100 and 98, respectively
The first and second surfaces 6 and 8 of the second heat transfer plate 4b are in contact with the first surface 6 of the first heat transfer plate 4a and the second surface 8 of the third heat transfer plate 4c. Centered on an axis that abuts each and the second heat transfer plate 4b coincides with the transverse center axis 22 of the second heat transfer plate 4b with respect to the first and third heat transfer plates 4a, 4c When rotated 180 degrees,
The male projections 68 and 70 of the first and fourth guides 60 and 66 of the second heat transfer plate 4b are of the third and second guides 64 and 62 of the first heat transfer plate 4a. Accommodated in female recesses 100 and 98, respectively
The male projections 68 and 70 of the first and fourth guides 60 and 66 of the first heat transfer plate 4a are of the third and second guides 64 and 62 of the second heat transfer plate 4b. Accommodated in female recesses 100 and 98, respectively
The male projections 88 and 90 of the second and third guides 62 and 64 of the third heat transfer plate 4c are of the fourth and first guides 66 and 60 of the second heat transfer plate 4b. Housed in female recesses 80 and 78, respectively
The male and female projections 88 and 90 of the second and third guides 62 and 64 of the second heat transfer plate 4b are of the fourth and first guides 66 and 60 of the third heat transfer plate 4c. Plate packs (2) for heat exchangers, each received in female recesses (80, 78).

Images